LOCOS trench isolation structures

ABSTRACT

Isolation structures having trenches formed on both sides of a LOCOS structure are disclosed. A semiconductor structure pad oxide layer is enlarged by local oxidation of silicon to form a field oxide. An etchback causes the thinnest portions of the field oxide to recede, such that a portion of the semiconductor substrate is exposed. An etch, through the exposed portion of the semiconductor substrate, forms a microtrench between the field oxide and the nitride layer with a lateral dimension that is less than that currently achievable by conventional photolithography. In another embodiment, formation of the microtrench is carried out as set forth above, but the nitride layer is immediately removed following trench formation. Alternatively, the pad oxide layer is stripped and a new oxide layer is regrown that substantially covers all exposed surfaces of active areas of the semiconductor substrate.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of application Ser. No. 10/899,609, filed Jul. 27, 2004, pending, which is a divisional of U.S. patent application Ser. No. 09/369,579, filed on Aug. 6, 1999, now U.S. Pat. No. 6,809,395, issued Oct. 26, 2004, which is a divisional of U.S. patent application Ser. No. 08/916,475, filed on Aug. 22, 1997, now U.S. Pat. No. 6,090,685, issued Jul. 18, 2000, all of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. The Field of the Invention

The present invention relates to the formation of semiconductor devices. In particular, the present invention relates to the formation of isolation trench structures for semiconductor devices. More particularly, the present invention relates to an inventive method for the formation of an inventive isolation microtrench at the edge of a field oxide region of a semiconductor device.

2. The Relevant Technology

In the microelectronics industry, a substrate refers to one or more semiconductor layers or structures which includes active or operable portions of semiconductor devices. In the context of this document, the term “semiconductor substrate” is defined to mean any construction comprising semiconductive material, including, but not limited to, bulk semiconductive material such as a semiconductive wafer, either alone or in assemblies comprising other materials thereon, and semiconductive material layers, either alone or in assemblies comprising other materials. The term substrate refers to any supporting structure including, but, not limited to, the semiconductor substrates described above.

The term “substrate assembly” is intended herein to mean a semiconductor substrate having one or more layers or structures formed thereon. As such, the substrate assembly may be, by way of example and not by way of limitation, a semiconductor substrate such as, N-well or P-well doped silicon having a gate oxide layer over an active area of the semiconductor substrate, a field oxide layer adjacent to the gate oxide layer, and a microtrench positioned between the gate oxide layer and the field oxide layer.

In the microelectronics industry, the process of miniaturization entails shrinking the size of individual semiconductor devices to make room for more semiconductor devices on a given unit area. With miniaturization, problems of proper isolation between semiconductor devices arise. When miniaturization demands the shrinking of individual devices, isolation structures must also be reduced in size. Attempts to isolate semiconductor devices from each other are currently limited to photolithographic limits of about 0.35 microns for isolation structure widths.

To form an isolation trench on a semiconductor wafer by photolithography, for example, the photoresist mask through which the isolation trench is etched generally utilizes a beam of light, such as ultraviolet (UV) light, to transfer a pattern through an imaging lens from a photolithographic template to a photoresist coating which has been applied to the structural layer being patterned. The pattern of the photolithographic template includes opaque and transparent regions with selected shapes that match corresponding openings and intact portions intended to be formed into the photoresist coating. The photolithographic template is conventionally designed by computer assisted drafting and is of a much larger size than the semiconductor wafer on which the photoresist coating is located. Light is shone through the photolithographic template and is focused on the photoresist coating in a manner that reduces the pattern of the photolithographic template to the size of the photolithographic coating which develops the portions of the photoresist coating that are unmasked and are intended to remain. The undeveloped portions are thereafter easily removed.

The resolution with which a pattern can be transferred to the photoresist coating from the photolithographic template is currently limited in commercial applications to widths of about 0.35 microns, or greater. In turn, the dimensions of the openings and intact regions of the photoresist mask, and consequently the dimensions of the shaped structures that are formed with the use of the photoresist mask, are correspondingly limited. Photolithographic resolution limits are thus a barrier to further miniaturization of integrated circuits. Accordingly, a need exists for an improved method of forming isolation trenches that have a size that is reduced from what can be formed with conventional photolithography.

The photolithography limit and accompanying problems of alignment and contamination are hindrances upon the ever-increasing pressure in the industry to miniaturize. Other problems that occur in isolation trench formation are, with trenches that are deep and wide in comparison to the size of the individual device that the trench is isolating, dielectric material such as thermal silicon dioxide that fills the trench tends to encroach upon the active area that the trench is supposed to isolate. Another problem is that wide and deep trenches tend to put a detrimental amount of stress upon the silicon of the active area that leads to defects such as delamination, fracture, and device failure.

Another problem that arises in isolation trench formation under current photolithographic limits is that with the limitations of trench widths, specific defects arise at the upper corners of the active areas. One such defect is called a Kooi corner defect. Removal of a Kooi defect requires growing a sacrificial oxide (SAC) and then subsequently removing it before a gate oxide can be grown over an active area. SAC growth can destructively remove substantially all semiconductive material, such as silicon, down to or near the bottom of the trench that has just been fabricated, thereby neutralizing the effect of trench formation. It would be an advancement in the art to find a method to avoid this defect. At the field edge of a LOCOS in silicon, there is a stress-induced defect upon growth of the LOCOS. The oxide thickness is thinner in a small space and thicker in a large space. Thus, with a small space, there exists difficulty in forming an isolation region because of the potential extent of growth of a LOCOS into the isolation region. A microtrench that avoids both the Kooi defect and the problems associated with growing a LOCOS would, therefore, be an advancement in the art.

What is needed is an inventive method of isolation trench formation that avoids the problems of the prior art such as alignment, photolithographic limitations, isolation trench filling that causes stress upon the active areas, and SAC processing that substantially neutralizes the effect of the isolation trench that is formed.

BRIEF SUMMARY OF THE INVENTION

In a first embodiment of the present invention, an isolation trench is formed in a semiconductor structure. A semiconductor structure consists of a semiconductor substrate, a pad oxide layer, a nitride layer, and a mask that has been used to pattern the nitride layer. The pad oxide layer is enlarged by local oxidation of silicon (LOCOS) to form a field oxide. An etchback is then carried out. The etchback causes a thin portion of the field oxide to recede such that a portion of the semiconductor substrate is exposed. The exposed portion has a lateral dimension that is less than currently achievable dimensions using photolithography. The inventive method etches through the exposed portion of the semiconductor substrate to form a microtrench. The microtrench forms between the field oxide and the nitride layer. The microtrench is next filled by oxide or nitride.

Following formation of the filled microtrench, a subsequent oxidation is carried out whereby the field oxide is enlarged. The enlarged field oxide encroaches downwardly into the semiconductor substrate, however, encroachment by the enlarged field oxide laterally into active areas is substantially resisted by the presence of the filled microtrench.

In another embodiment of the present invention, formation of the microtrench is carried out as set forth above, but the nitride layer is removed immediately following microtrench formation. In a first alternative technique of this embodiment, the pad oxide layer is stripped and a new oxide layer is regrown that substantially covers all exposed surfaces of the active areas of the semiconductor substrate. This means that the regrown oxide layer will encroach into all exposed surfaces of active areas that include the microtrench.

In yet another embodiment of the present invention, microtrench formation is carried out by pattering the nitride layer and then by performing an etch upon the pad oxide layer. Etching of the pad oxide layer is carried out as the pad oxide layer etches substantially uniformly at regions distant from the patterned nitride layer. During the pad oxide layer etch, the etchant concentrates itself against the nitride layer where the nitride layer touches the pad oxide layer such that pad oxide layer etching is accelerated at the interface with the nitride layer. Because of accelerated etching at this location, a breach in the pad oxide layer forms before etching of the pad oxide layer has generally removed all of the pad oxide layer. Control of the inventive etching method allows for the width of the breach to be narrower than an area otherwise achievable by photolithography according to present photolithographic techniques.

Following formation of the breach in the pad oxide layer, a microtrench is etched through the breach into the semiconductor substrate. A cover layer, for example, a nitride film, is formed both within the microtrench and upon the nitride layer. A nitride spacer etch is then carried out to remove substantially all of the cover layer except for those portions that are within the microtrench and upon the side walls of nitride layer, thus forming a nitride isolation microtrench. Formation of a field oxide follows and encroachment of oxide into areas protected by the nitride isolation microtrench is resisted.

These and other features of the present invention will become more fully apparent from the following description and appended claims, or may be learned by the practice of the invention as set forth hereinafter.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

In order to illustrate the manner in which the above-recited and other advantages of the invention are obtained, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the invention and are not, therefore, to be considered limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:

FIG. 1 is an elevational cross-sectional view of a semiconductor structure that comprises a semiconductor substrate, a pad oxide layer, a patterned nitride layer, and a mask.

FIG. 2 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 1 after further processing, wherein a field oxide has been grown upon exposed portions of the pad oxide layer, thereby substantially enlarging the thickness of the pad oxide layer at regions most distant from the nitride layer, and also, thereby, leaving a thin portion immediately touching the laterally exposed surface of the nitride layer.

FIG. 3 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 2 after further processing, wherein a selective etch of the field oxide has caused the thin portion of the field oxide to retract away from the laterally exposed surface of the nitride layer, thereby exposing a portion of the semiconductor substrate that has an exposed width that is smaller than an exposed width that would be accomplishable by current photolithographic techniques.

FIG. 4 illustrates an elevational cross-sectional view of the semiconductor structure depicted in FIG. 3 after further processing, wherein a microtrench has been etched into the semiconductor substrate and wherein the etch is self-aligned between the nitride layer and the field oxide at a width dimension that is smaller than that achievable by current photolithographic techniques.

FIG. 5 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 4 after further processing, wherein the microtrench has been filled with a cover layer comprising either a layer of oxide or nitride that is deposited by chemical vapor deposition (CVD), or a thermally grown layer of oxide or nitride, and in which a second etch has removed all of the cover layer except for those portions filling the microtrench and forming a spacer upon the nitride layer.

FIG. 6 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 5 after further processing, wherein the field oxide has been enlarged after a LOCOS process and in which a cap oxide has been formed upon the upper surface of the nitride layer.

FIG. 7 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 5 or 6 after further processing, wherein the cap oxide layer, the nitride layer, the pad oxide layer, and some of the portions of the nitride spacer have been removed by various steps, and wherein a gate oxide layer has been grown upon active areas of the semiconductor substrate thus forming a semiconductor structure with a nitride or oxide-filled microtrench.

FIG. 8 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 4 after further processing in an alternative embodiment of the present invention, wherein the nitride layer and optionally the pad oxide layer have been removed prior to filling of the microtrench.

FIG. 9 illustrates an elevational cross section of the semiconductor structure depicted in FIG. 8 after further processing, wherein the microtrench has been filled with an oxide layer that may comprise a sacrificial oxide layer or a deposited oxide layer, or wherein the microtrench has been filled with a nitride layer that may comprise a sacrificial nitride layer or a deposited nitride layer.

FIG. 10 illustrates an elevational cross section of the semiconductor structure depicted in FIG. 8 after further processing, wherein the optional sacrificial layer has been removed and a gate oxide layer has been grown upon the active area of the semiconductor substrate, thus forming isolation microtrench-isolated active areas with a gate oxide thereupon.

FIG. 11 illustrates an elevational cross section of the semiconductor structure depicted in FIG. 1 after optional further processing, wherein a pad oxide layer etch that causes intensified etching effects against and next to the nitride layer has created a breach within the pad oxide layer at a width dimension smaller than that achievable by current photolithographic techniques.

FIG. 12 illustrates an elevational cross section of the semiconductor structure depicted in FIG. 11 after further processing, wherein a microtrench has been etched into the semiconductor substrate and wherein the etch is self-aligned between the nitride layer and the edge of the unbreached portion of the pad oxide layer at a width dimension that is smaller than that achievable by current photolithographic techniques.

FIG. 13 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 12 after further processing, wherein the microtrench has been filled with a cover layer of either a CVD oxide or a nitride, or wherein the microtrench has been filled with a thermally grown oxide or nitride, and in which a second etch has removed all of the cover layer except for those portions filling the microtrench and forming a spacer upon the nitride layer.

FIG. 14 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 13 after further processing, wherein the field oxide has been enlarged after a LOCOS process.

FIG. 15 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 11 after further processing, wherein a microtrench that is shallower than that depicted in FIG. 12 has been etched and filled according the methods of the present invention.

FIG. 16 is an elevational cross-sectional view of the semiconductor structure depicted in FIG. 15 after further processing, wherein material has been removed from the microtrenches and replaced with another material of a composition different from that of the first material that previously filled the microtrenches.

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to formation of isolation microtrenches in a width range that is smaller than that achievable by photolithographic techniques. This technology is particularly useful in fabricating from 64 meg to 4 gig DRAM devices.

In a first embodiment of the present invention illustrated in FIG. 1, a semiconductor structure 10 is shown as having a semiconductor substrate 12, which is by way of non-limiting example an N-doped silicon material. A pad oxide layer 14 on semiconductor substrate 12 acts as a stress-reduction barrier. A nitride layer 16 on pad oxide layer 14 has at least one lateral surface 20 thereon, and a mask 18 is also shown as having been used to pattern nitride layer 16. Nitride layer 16 also acts as an oxidation barrier for the portion of semiconductor substrate 12, over which it is disposed. Pad oxide layer 14 is formed of an oxide in the thickness range of from about 30 Å to about 300 Å, preferably in the range of from about 60 Å to about 250 Å, more preferably in the range of from about 90 Å to about 200 Å, and, most preferably, in the range of less than 200 Å.

Formation of an isolation microtrench by the inventive method is further illustrated in FIG. 2, wherein pad oxide layer 14 has been enlarged by local oxidation of silicon (LOCOS) to form a first field oxide 22. First field oxide 22 comprises a thin portion 24 adjacent to and touching lateral surface 20 of nitride layer 16, and a thick portion 26 that is generally at a location equidistant between neighboring patterned nitride layers 16.

Following formation of first field oxide 22, an etchback is carried out to expose a portion of semiconductor substrate 12. Etchback of first field oxide 22, illustrated in FIG. 3, causes a retraction of thin portion 24 of first field oxide 22 to form an exposed substrate area 28. Retraction of thin portion 24 of first field oxide 22 can be controlled by the inventive method to achieve exposed substrate area 28 that has a lateral dimension L that is less than currently achievable dimensions using photolithography. By the inventive method, exposed substrate area 28 has a lateral dimension L that is in a range from about 50 Å to about 10,000 Å. As such, semiconductor structure 10 is ready for an isolation microtrench etch.

FIG. 4 illustrates the results of an isolation microtrench etch according to the inventive method, wherein further processing of semiconductor structure 10 illustrated in FIG. 3 has been accomplished. In FIG. 4 it can be seen that a microtrench 30 has formed between first field oxide 22 and nitride layer 16. An etch recipe for the isolation microtrench etch is selective to both first field oxide 22 and nitride layer 16, thereby virtually etching only microtrench 30 and leaving first field oxide 22 and nitride layer 16 unetched.

With the inventive method, a width dimension for a microtrench that is smaller than 50 Å is achievable, but process limitations, such as getting an oxide to fill into the narrow dimension of less than 50 Å, become difficult. Additionally, microtrenches having a width that is the diameter of large atoms may cause electricity to travel from the active area, through some dielectric materials that fill the microtrench, and into other regions of the semiconductor structure.

Depending upon the depth of microtrench 30, it is an option of the inventive method to implant doping materials into the bottom of microtrench 30 to form a doped trench bottom 32. Preferably, implantation in this manner may be done, for example, when microtrench 30 is relatively shallow compared to the ultimate thickness of the field oxides that are situated on opposite sides of active areas of semiconductor structure 10.

The microtrench obtained by the inventive method overcomes the problems of the prior art of creating detrimental amounts of stress upon the semiconductive material of the active area, such as silicon. The inventive microtrench and its method of making result in combined width and depth dimensions that are substantially less than that of prior art trench. Moreover, the inventive microtrench applies substantially no detrimental amount of stress upon the semiconductive material of the active area.

Various materials may be used in the method of the present invention, depending upon the specific application. When the oxidation barrier is nitride layer 16 and first field oxide 22 is a thermal silicon oxide, the inventive method can be used to form a microtrench having a width in a range from about 100 Å to about 1,000 Å and a depth in a range from about 0.1 microns to about 0.25 microns, where the microtrench is situated in between neighboring nitride layers 16 separated by about 0.3 microns. For such a microtrench, there will be substantially no detrimental stress.

A simple dimensional analysis of microtrench aspect ratio (trench depth divided by trench width) compared to the aspect ratio of the active area (active area height divided by active area width) will assist the fabricator in determining what microtrench width is limiting to prevent detrimental amounts of stress upon the semiconductive material of the active area. It is noted that this simple ratio causes both trench depth and active area height to be cancelled, because they are the same. Thus, a simple ratio of trench aspect ratio to active area aspect ratio comprises merely dividing one width by the other, for example, dividing trench width by active area width. In the present invention it is considered to be a dimensional analysis guide for structures that avoid destructive stresses caused by trenches. For example, in a structure with a 0.3 micron distance between two adjacent nitride layers, a microtrench can be formed in an N-well region of a semiconductor substrate that has a width in a range from about 100 Å to about 1,000 Å, and a depth from about 0.1 microns to about 1 micron.

The inventive method is further illustrated in FIG. 5, wherein microtrench 30 has been filled. Filling can be accomplished by deposition of a dielectric material within microtrench 30. A filled microtrench 34 has a nitride spacer 36, thereover, in contact with lateral surfaces 20 of nitride layer 16. The accomplishment of filled microtrench 34, according to the depiction in FIG. 5, is done, by way of non-limiting example, by chemical vapor deposition (CVD) of an oxide material such as from tetraethyl ortho silicate (TEOS), followed by an anisotropic etch to remove substantially all the CVD oxide upon first field oxide 22 and upon the upper surface 38 of nitride layer 16.

In one embodiment, the method of the present invention can be performed in an AME P5000 CVD chamber (available from Applied Materials Co., Santa Clara, Calif.). A TEOS (tetraethoxysilane) based silicon dioxide film is formed within microtrench 30 by standard CVD processes in the CVD chamber. Such standard CVD processes may include plasma enhanced CVD (PECVD), low pressure CVD (LPCVD), and thermal CVD (THCVD). The TEOS-based silicon dioxide film is formed by reacting TEOS and ozone in the CVD chamber, such as under the following conditions: 3900 sccm oxygen with 5% by weight ozone and 1500 sccm Helium saturated with TEOS (40° C. TEOS temperature), at 30 Torr and 400° C. Also, TEOS may be deposited in a vacuum process that may have a chamber pressure in a range from about 1,000 to 3,000 milliTorr. Alternatively, for TEOS formation, a high-density plasma oxide deposition may be done. Alternatively, filled microtrench 34 may be a simple oxide or nitride growth to be grown selectively within microtrench 30, whereby growth is chosen chemically to selectively grow upon the exposed surfaces of semiconductor substrate 12 within microtrench 30.

Following formation of filled microtrench 34 with its optional formation of spacer 36 upon nitride layer 16, a subsequent oxidation illustrated in FIG. 6, is carried out whereby first field oxide 22 (see FIG. 5) is further grown to form a second field oxide 42 that comprises a thicker field oxide layer than first field oxide 22. Second field oxide 42 encroaches downwardly into semiconductor substrate 12. However, encroachment of oxide into a semiconductor substrate active area 44 is substantially resisted by virtue of the presence of filled microtrench 34.

FIG. 7 illustrates further processing of semiconductor structure 10 according to the inventive method, wherein a nitride etchback has removed nitride layer 16 (see FIG. 6). Depending upon the etch recipe that is chosen, the portions of filled microtrench 34 and spacer 36 (FIG. 6) may be partially removed or entirely removed as illustrated from left to right on opposite sides of dashed line D, respectively, in FIG. 7. When filled microtrench 34 and spacer 36 are an oxide such as silicon dioxide, the etch recipe that removes substantially all of spacer 36 will also remove some of the exposed surface of second field oxide 42, as illustrated on the right side of dashed line D in FIG. 7.

Following removal of nitride layer 16, various processing options are available. When substantial contamination or oxidation of semiconductor substrate 12 may have occurred, and, particularly, contamination of active area 44, it may be preferable to grow a sacrificial oxide (SAC) layer into active area 44 and then strip it, for example, using a 100:1 HF:deionized water strip. When contamination or oxidation has not required formation of a SAC layer, a simple strip of pad oxide layer 14 (FIG. 6) may be carried out. Following removal of pad oxide layer 14, whether by SAC growth or simple stripping thereof, a gate oxide layer 46, as seen in FIG. 7, is grown. Additionally, formation of a SAC layer may be carried out simultaneously with formation of filled microtrench 34, whereby a single oxidation is carried out, such as a thermal oxidation, followed by a strip of the SAC layer, optionally leaving the oxide in microtrench 30, and, finally, the formation of gate oxide layer 46.

In yet another embodiment of the present invention, formation of microtrench 30 is carried out as illustrated in FIGS. 1-4. However, following formation of microtrench 30, nitride layer 16 is removed, for example, by stripping. Stripping of nitride layer 16 is illustrated, as accomplished, in FIG. 8. In a first alternative of this embodiment of the present invention, pad oxide layer 14 is also stripped, as seen on the right side of dashed line D of FIG. 8, and a new oxide layer 48, as seen in FIG. 9, is regrown that substantially covers all exposed surfaces of active area 44 including within microtrench 30. In a second alternative of this embodiment, nitride layer 16 is removed, but pad oxide layer 14 is not. In either alternative of this embodiment, new oxide layer 48 will encroach into active area 44 approximately up to one half the thickness of new oxide layer 48 as it forms upon an upper surface 56 of active area 44.

New oxide layer 48 may optionally be removed by an etchback that is selective to active area 44 and semiconductor substrate 12, and this etchback may be carried out to remove substantially only those portions of new oxide layer 48 that lie upon upper surface 56, but not those portions that lie within microtrench 30.

Alternatively, as illustrated in FIG. 10, an etchback step may be carried out that removes substantially all of new oxide layer 48 and both those portions that lie upon the upper surface of second field oxide 42 and within microtrench 30. In this alternative embodiment, a nitride cover layer 58 is grown, deposited, or otherwise formed within microtrench 30, as a final isolation filled microtrench 34. Further thermal processing of semiconductor structure 10 may then be carried out, for example, to form second field oxide 42, and encroachment into active area 44 will be substantially resisted by the nitride material in microtrench 30.

In yet another embodiment of the present invention, microtrench formation is carried out by forming nitride layer 16 with mask 18 and then by performing an etch upon pad oxide layer 14. The structure depicted in FIG. 1 is a proper starting point for this embodiment of the present invention. Etching of pad oxide layer 14 is carried out according to the illustration depicted in FIG. 11. Etching of pad oxide layer 14 is carried out substantially uniformly at regions distant from lateral surface 20 of nitride layer 16.

The etchant is, preferably, selective to nitride layer 16 and does not substantially etch nitride layer 16, but rather concentrates the etch against lateral surface 20 of nitride layer 16 at the intersection with pad oxide layer 14, such that etching is accelerated at this location. Because of accelerated etching at this location, a breach having a width L forms in pad oxide layer 14 so as to form exposed substrate area 28. Preferably, the breach will be formed before pad oxide layer 14 is substantially penetrated. Width L has a width in a range from about 50 Å to about 10,000 Å, preferably, from about 100 Å to about 2,000 Å, and, most preferably, from about 500 Å to about 1,000 Å. Control of the inventive etching method allows for the surface area of exposed substrate area 28 to be narrower than an exposed surface area otherwise achievable by conventional photolithography. The etch technique of this embodiment allows for an etch recipe that is selective to both pad oxide layer 14 and nitride layer 16. Although these are the only two surfaces that are initially exposed, once the breach is formed, accelerated etching occurs in silicon substrate 12 to form microtrench 30 (FIG. 12). A similar width L will be the width of microtrench 30.

The foregoing etch can be precisely controlled by known principles of etching to form a breach of a desired aperture or width in pad oxide layer 14. Specifically, it is known that at a constant temperature, the mean free path of etchant molecules between collisions is inversely proportional to the pressure. It is also known that the path distance between collisions is substantially less than the mean free path for the etchant molecules against nitride layer 16 that collide downwardly and toward pad oxide layer 14 and that strike against nitride layer 16 at a height above pad oxide layer 14 because etching in a rebound region of these etching molecules will be substantially intensified. Given the foregoing principles of etching, a breach of a desired aperture or width in pad oxide layer 14 can thus be formed by controlling temperature and pressure during the etch thereof.

Although etching of pad oxide layer 14 may continue after formation of exposed substrate area 28 with a single pad oxide layer 14 and nitride layer 16 using a selective etch recipe, as illustrated in FIG. 11, a preferred alternative of this embodiment comprises exchanging the etch recipe from that which was employed to etch exposed surface area 28 to an etch recipe that is highly selective to pad oxide layer 14 and nitride layer 16. As such, etching with a changed etch recipe will form a microtrench 30, as seen in FIG. 12, that is confined to the size of the breach that is entirely within exposed substrate area 28 as illustrated in FIG. 11.

Following formation of microtrench 30, mask 18 is removed by conventional stripping. As an alternative means of removing mask 18, thermal removal of mask 18 can be carried out simultaneously with the forming of filled microtrench 34. In this alternative technique, thermal processing effectively drives off mask 18 by causing the components of mask 18 to volatilize, while the enhanced temperatures and the presence of oxygen used for thermal mask removal cause oxidation within microtrench 30. In an alternative technique of this embodiment, removal of mask 18 is followed by oxidation that also forms an oxide cap 50 upon nitride layer 16, as analogously illustrated in FIG. 6.

Because oxidation within microtrench 30 can be followed by several steps of oxidation, for example, SAC layer oxidation, encroachment into active area 44 may continue. In a preferred technique, microtrench 30 is filled by the formation of a nitride layer (not shown) which is followed by an anisotropic spacer etch to form filled microtrench 34 and spacer 36, as seen in FIG. 7. After formation of a nitride within microtrench 30, a subsequent oxidation of semiconductor structure 10 allows for growth of pad oxide layer 14 into a field oxide region, such as first field oxide 22, as seen in FIG. 14. Encroachment of oxide into active area 44 is substantially resisted by virtue of formation of nitride cover layer 58 that forms filled microtrench 34 (FIG. 10).

When microtrench 30 is shallow, meaning first field oxide 22 encroaches substantially no deeper into semiconductor substrate 12 than the bottom of microtrench 30, formation of first field oxide 22 can be carried out without any substantial encroachment into active area 44, as illustrated in FIG. 15. Following formation of first field oxide 22, a dry etch decap may be carried out to remove any oxide, any nitride, or the like, that may have formed upon upper surface 38 of nitride layer 16, as seen in FIG. 5.

Following a dry etch decap, a wet nitride etch is carried out to substantially remove all exposed nitride upon semiconductor structure 10, which includes the nitride in microtrench 30 and nitride layer 16. The wet nitride etch recipe is highly selective to first field oxide 22 and to pad oxide layer 14. With removal of all nitride within filled microtrench 34, an oxide may be grown in the stead of filled microtrench 34 to form a field oxide spacer 54, as seen in FIG. 16, that substantially fills microtrench 30 and coats first field oxide 22 as it converts into second field oxide 42.

Following formation of field oxide spacer 54, a sacrificial oxide layer formation and removal technique may be carried out to remove pad oxide layer 14, or a simple etchback may be carried out that removes incidental portions of second field oxide 42 and field oxide spacer 54. Following these optional processes, gate oxide layer 46 may be formed to cover active area 44.

In microtrench formation, according to the present invention, a composite filled microtrench 34 and nitride spacer 36 may be fabricated, whether it be a self-aligned microtrench formed between an edge of first field oxide layer 22 and nitride layer 16, or between pad oxide layer 14 and nitride layer 16. The inventive method may be practiced by forming a first cover layer comprising an oxide in microtrench 30 and upon nitride layer 16, followed by an etch, for example, a wet isotropic etch, that removes all of the oxide cover layer except for those portions within microtrench 30. Following removal of the oxide cover layer, except for those portions within microtrench 30, a second cover layer comprising a nitride film is formed upon both nitride layer 16 and first field oxide 22. A second etch, by way of non-limiting example, an anisotropic etch, removes portions of the second cover layer to leave nitride spacer 36 above filled microtrench 34 and upon nitride layer 16.

The purpose of forming a composite nitride spacer 36 and filled microtrench 34 is to achieve an easily formed isolation material in microtrench 30, such as a thermal oxide that forms filled microtrench 34, followed by a nitride cap comprising nitride spacer 36 as the material above filled microtrench 34. With the nitride cap comprising nitride spacer 36 as the material above filled microtrench 34, further oxidation, for example, of first field oxide 22 to form second field oxide 42, can be carried out. Encroachment into active area 44 by oxide material through filled microtrench 34, which in this technique is an oxide, is substantially resisted by the nitride cap which is nitride spacer 36 above filled microtrench 34. As in techniques set forth above, etching may be carried out to either partially or totally remove nitride spacer 36 following thermal processing.

The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims and their combination in whole or in part, rather than by the foregoing description. All changes that come within the meaning and range of equivalency of the claims are to be embraced within their scope. 

1. An isolation structure of a semiconductor device comprising: a trench extending between a gate oxide layer and a field oxide region in a semiconductor substrate, the trench being filled with a dielectric material comprising a nitride; a spacer situated on a lateral surface of the field oxide region and a lateral surface of the gate oxide layer, the spacer comprising a dielectric material an intersection of the trench with the top surface of the semiconductor substrate having a first edge opposite a second edge; the field oxide region in contact with the first edge; and a gate oxide layer in contact with the second edge.
 2. An isolation structure in a semiconductor structure that includes a pad oxide layer upon a semiconductor substrate having a top surface and an oxidation barrier layer upon the pad oxide layer, wherein the oxidation barrier layer has a lateral surface thereon, the isolation structure comprising: a trench extending between the oxidation barrier layer and a region in the semiconductor substrate, the trench being filled dielectric material comprising a nitride; and a spacer composed of a second dielectric material, different from the first dielectric material, the spacer situated on the lateral surface of the oxidation barrier layer.
 3. The isolation structure of claim 2, wherein the second dielectric material comprises an oxide.
 4. The isolation structure of claim 2, further comprising a dopant at a bottom of the trench.
 5. The isolation structure of claim 2, wherein: the trench extends within the semiconductor substrate below the top surface of the semiconductor substrate; and the trench has a maximum width of less than about 2,000 Å at an intersection with the top surface of the semiconductor substrate.
 6. The isolation structure of claim 2, wherein the first dielectric material extends above the top surface of the semiconductor substrate.
 7. An isolation structure comprising: a semiconductor substrate having a first active region and a separate second active region each of the first and second active regions extending to a top surface of the semiconductor substrate; a field oxide region having a convex top surface opposite a convex bottom surface, wherein the convex bottom surface extends within the semiconductor substrate below the top surface of the semiconductor substrate to a first depth, the field oxide region is separated from the first and second separate active regions, and the convex top surface extends above the top surface of the semiconductor substrate; a first isolation trench extending into the semiconductor substrate, the first isolation trench filled with a dielectric material comprising a nitride, and having a first spacer formed thereto, the first spacer extending above the top surface of the semiconductor substrate, wherein: the first isolation trench has first and second opposite sides; the first side of the first isolation trench in contact with the field oxide region; and the second side of the first isolation trench in contact with the first active region; and a second isolation trench extending into the semiconductor substrate, the second isolation trench filled with a dielectric material comprising a nitride and having a second spacer formed thereto, the second spacer extending above the top surface of the semiconductor substrate, wherein: the second isolation trench has first and second opposite sides; the first side of the second isolation trench in contact with the field oxide region; and the second side of the second isolation trench in contact with the second active region.
 8. An isolation structure, comprising: a semiconductor substrate comprising a semiconductive material and having first and second separate active regions each extending to a top surface of the semiconductor substrate; a field oxide region having a curved top surface and an opposite curved bottom surface, wherein: the curved bottom surface projects within the semiconductor substrate below the top surface of the semiconductor substrate; the field oxide region is separated from the first and second separate active regions; and the curved top surface projects above the top surface of the semiconductor substrate; a pair of nitride dielectric extensions each: having opposite first and second sides; projecting within and in contact with the semiconductive material of the semiconductor substrate below the top surface of the semiconductor substrate; contacting a respective active region on the first side thereof; being out of contact from one of an active region on the second side thereof; and projecting above the top surface of the semiconductor substrate; and a pair of layers each of which: is upon a respective one of the active regions; and intersects a respective one of the dielectric extensions on one of the opposite sides of the field oxide region; wherein each of the dielectric extensions constitutes a structural barrier between the opposite first and second sides, configured to prevent the contact with a respective one of the active regions and the field oxide region, and configured to prevent the encroachment of material from the field oxide region into the respective active region.
 9. An isolation structure including a semiconductor substrate having a plurality of active regions extending to a top surface of the semiconductor substrate, the isolation structure comprising: a pair of dielectric trench structures comprising a nitride, each of the pair of dielectric trench structures in contact with one of the active regions and extending below and above the top surface of the semiconductor substrate and respectively lower and higher than a field oxide region within the semiconductor substrate, wherein the field oxide region is physically separate from the plurality of active regions, is longer than it is high, and has opposite sides each of which makes contact with a respective one of the trench structures; and oxide layers upon the active regions and making contact with the field oxide region.
 10. An isolation structure including a semiconductor substrate having a plurality of active regions and a top surface of the semiconductor substrate, the isolation structure comprising: a pair of dielectric trench structures each of which: including a top portion comprising a nitride upon a bottom portion comprising an oxide; in contact with one of the active regions; extending below the top surface of the semiconductor substrate to a first depth; and extending above the top surface of the semiconductor substrate to a first height; a field oxide region extending into the semiconductor substrate to a second depth less than the first depth, wherein the field oxide region: extends above the top surface of the semiconductor substrate to a second height; is physically separate from the plurality of active regions; is longer than it is high; and has opposite sides each of which makes contact with the nitride of a respective one of the dielectric trench structures; and oxide layers upon each of the active regions and making contact with the field oxide region.
 11. The isolation structure of claim 10, wherein the first height is greater than the second height. 